CA2644312A1 - Turbine engine turbine or compressor stage - Google Patents

Abstract

Turbomachine turbine or compressor stage, comprising a paddle wheel surrounded by a sectorized ring carried by a casing, each ring sector (22) comprising a circumferential rim (34) clamped radially on a rail of the casing by two bolts ( 240) are engaged on the circumferential end portions of the flange of this ring sector and on corresponding parts of the casing rail.

Description

Turbine turbine or compressor stage The present invention relates to a turbine stage or compressor of a turbomachine such as a turbojet engine or a turboprop aircraft, comprising a rotary wheel mounted the inside of a cylindrical or frustoconical ring formed by sectors ring circumferentially hung end-to-end on a housing of the compressor or turbine.
Each ring sector comprises at one of its ends a circumferential flange which is clamped radially on an annular rail of casing by means of an elastic latch with section substantially in C, which is engaged axially on the sump rail and on the sill circumferential ring sector.
In the present technique, the latches are arranged circumferentially end to end and therefore form means of ring locks that extend over 3600. The locks each have a width or angular extent that is at least equal to that of a sector the number of locks is therefore less than or equal to the number of ring sectors.
When the locks each have an angular or angular which is ale to that of the ring sectors, each lock is in general engaged on the circumferential rim of a single sector d ring so that the lateral ends of the lock are substantially aligned with the longitudinal edges of the ring sector.
Each latch is engaged on the crankcase rail and on the ledge circumferential ring sector with some radial prestressing.
In operation, it appears a guardian of relatively radial direction in each ring sector, which is causes a decambrage of this sector of ring. This phenomenon is essentially translates into an increase in the radius of curvature of the

2 ring sector, which increases the stresses in the middle part lock and can reduce its life.
The purpose of the invention is in particular to provide a simple solution, effective and economical to this problem.
It proposes for this purpose a stage of turbine or compressor of turbomachine, comprising at least one paddle wheel surrounded by a sectorized ring carried by a housing and comprising a rim circumferential tightened radially on an annular rail of the housing by elastic locks with a substantially C-section which are engaged axially on the casing rail and on the rim of the ring, characterized in that what each ring sector is kept on the crankcase rail by at minus one lock, which is engaged only on one end part circumferential edge of the ring sector and on a part corresponding crankcase rail.
Thus, according to the invention, the locks are at a certain distance circumferentially from each other and are engaged only on end portions of the ring sectors and on parts corresponding rail. No lock is engaged on a middle part of a ring sector and on the corresponding part of the crankcase rail. The middle part of each ring sector can therefore move freely in the radial direction during the operation of the turbomachine without risk of damaging the locks.
Each ring sector is thus held radially on the rail crankcase by at least one of its ends. As opposed to the technique previous, the locks are not arranged adjacently. The locking means do not extend continuously over 360, this which makes it possible to significantly reduce their mass. Prestressing radial bolts enough to immobilize them in the circumferential direction sure the crankcase rail and on the edges of the ring sectors. Systems of circumferential locking of the locks can also be provided in the

3 where the radial prestressing of the bolts would not be sufficient or would be zero. These locks are substantially identical to each other.
According to another feature of the invention, the locks have a width or angular extent that is less than that of a sector ring.
Each ring sector can be maintained on the crankcase rail by a single lock, this lock being engaged on an end portion circumferential edge of the ring sector and on a part corresponding crankcase rail. The lock can hold a radially only ring sector, or else can maintain two ring areas when riding on two adjacent ring sectors.
Alternatively, each ring sector is maintained on the rail of casing by two latches engaged on the circumferential end portions the rim of the ring sector and on corresponding parts of the rail of crankcase. Each of these latches can hold an end portion of edge of the ring sector or even an end portion of the edge of an adjacent ring sector if this lock is mounted astride the edges of these two ring areas.
The locks can be located at a distance from one another circumferential direction, this distance being for example greater or equal to the width of a lock.
Each latch can have an angular width or range that is less than about half, preferably less than about one-third, and for example, less than about a quarter, of that of a ring sector.
The invention also relates to a compressor or a turbine of turbomachine, characterized in that it comprises at least one turbine or compressor stage as described above.
The invention also relates to a turbomachine, such as a turbojet engine or an airplane turboprop engine, characterized in that comprises at least one turbine or compressor stage as described above.

4 The invention will be better understood and other features, details and advantages of it will become clearer when you read the description which follows, given by way of non-limiting example and with reference to the drawings in which:
FIG. 1 is a partial diagrammatic half-view in axial section of a turbine stage according to the prior art;
FIG. 2 is a schematic perspective view of a ring sector and a lock of the stage of Figure 1;
FIG. 3 is a very partial schematic front view of the sector ring of Figure 2, seen from downstream;
FIG. 4 is a schematic perspective view of a ring sector and a lock of the stage according to this irivention;
FIG. 5 is a schematic perspective view of a ring sector and two locks of an alternative embodiment of the invention;
FIG. 6 is a schematic view from above of the ring sector and locks of Figure 5.
Referring first to Figure 1 which shows a turbine stage 10 of a turbomachine such as a turbojet engine or a turboprop engine airline. This stage 10 comprises a distributor 12 formed of a row annular fixed vanes 14 carried by a casing 16 of the turbine, and a impeller 18 mounted upstream of the distributor 12 and rotating in a sectorized ring 20 formed of a plurality of sectors 22 that are worn circumferentially end to end by the casing 16 of the turbine.
The distributor 12 comprises two walls of external revolution 24 and internal (not visible), respectively, which delimit between them the vein ring of gas flow in the turbine and between which radially extend the vanes 14. The distributor fixing means comprise at least one upstream radial tab 26 connected to its periphery external to a cylindrical flange 28 facing upstream and intended to be engaged in an annular groove 30 facing downstream of the housing 16.

Each ring sector 22 comprises at its upstream ends and downstream of the circumferential rims 32, 34 hooking on the housing 16 of the turbine. The upstream circumferential rims 32 of the ring sectors are oriented upstream and are engaged on a cylindrical rim 36 oriented

5 downstream of the casing 16. The downstream circumferential flanges 34 of the sectors are oriented downstream and are clamped radially on a cylindrical rail of the casing by means of locks 40 to C section whose opening is oriented axially upstream and which are engaged axially by elastic deformation from downstream on the casing rail 38 and the flanges circumferential downstream 34 ring sectors. The downstream edges 34 of the ring sectors and the rail 38 of the housing have substantially the same radius of curvature.
Each latch 40 comprises two circumferential walls 42 and 44, radially outer and radially inner respectively, which are connected between them at their downstream ends by a radial wall 46, and which are engaged respectively outside the guard rail 38 and inside downstream flanges 34 of the ring sectors.
The radial wall 46 of the latch 40 is interposed axially between the downstream ends of the rail 38 and flanges 34, and the radial wall 26 of the distributor 12 located downstream, to prevent the lock 40 from moving axially downstream and disengage from the crankcase rail 38 and ledges 34 of ring areas.
As can be seen in FIG. 2, each ring sector 22 is associated with a single latch 40 in the prior art. The crankcase 38 has not been shown in this figure for the sake of clarity. The lock has a width L or angular extent that is substantially the same to that H of the ring area. In the mounting position shown in 2, the lateral faces 48 of the lock extend in the extension radial side faces 50 of the beam sector. The lateral faces 48 of each lock are located a short distance in the direction

6 circumferential side faces of adjacent locks that are connected between them in an almost contiguous way.
The latch 40 is preferably engaged on the casing rail 38 and on the circumferential rim 34 of the ring sector with some radial prestressing. For this, the radial distance between circumferential walls 42, 44 of the unlatched latch (corresponding to the radial dimension of the bolt opening) is lower, for example some tenths of a millimeter, at the sum of the thicknesses in radial direction of the casing rail 38 and the downstream edge 34 of the sector. The latch 40 is deformed elastically in the radial direction, by away from its circumferential walls 42, 44, during its axial engagement on the rail 38 and the downstream edge 34 of the sector.
In operation, the ring sector 22 is subjected to a gradient significant temperature in the radial direction, which translates into a unclamping the ring sector which then has a greater radius of curvature important that in the unconstrained state, its radius of curvature greater than that of the rail 38 of the housing. FIG. 3 shows the shape and the position of the downstream flange 34 of the ring sector in the free state without stress in continuous lines, and in the decambred state in dashed lines.
The unclamping of the ring sector causes a radial displacement J
towards the inside of the circumferential rim 34 of the ring sector, this displacement J varying along the circumferential dimension of the sector and being maximal at the middle part of this sector. This decampling results in a significant increase in the constraints in the middle part of the latch 40, which can reduce its life.
The invention makes it possible to remedy this problem by maintaining the ring sectors 22 on the casing rail 38 by means of locks which are engaged only on the end portions of the ledges circumferential downstream 34 ring sectors. The middle parts of the edges 34 sectors are then free to move in operation

7 without making efforts to locks that are far enough away from these areas of stress concentration.
In the embodiment shown in FIG. 4, the latch 140 has a width L 'or angular extent much lower than that of the sector ring 22, which is identical to the ring sectors of the technique earlier. The width L 'of the latch 140 is less than half, of preferably less than one third, and for example less than one quarter, of the width H of the ring sector 22. Each ring sector 22 is associated to a single latch 140 which is engaged on an end portion of the flange 34 of the sector and on a corresponding part of the guard rail 38 (no represented for the sake of clarity). The number of locks is therefore in this case identical to the number of ring sectors.
In the variant embodiment shown in FIGS. 5 and 6, the ring sector 22 is associated with two locks 240 that are engaged on the end portions, respectively, of the downstream edge 34 of the sector of ring and on corresponding parts of the housing rail 38. The number of locks is then double the number of ring sectors.
The locks 240 are substantially identical to each other and to the latch 140 of Figure 4 and are located at a relatively circumferential distance important from each other, this corresponding circumferential distance for example, the sum of the widths of two or three locks.
As in the prior art, latches 140 and 240 are prevented from moving axially downstream by bearing on the wall radial 26 of the distributor 12 located downstream (Figure 1). Prestressing radial latches 140, 240, when mounted on the housing rail 34 and on the downstream edges 38 ring sectors, enough to immobilize them in the circumferential direction. In the case where this radial prestressing is no or insufficient to lock the locks in the direction circumferential circumferential circumferential locking systems are provided.
locks.

Claims (11)

1. Stage of turbine or turbomachine compressor, comprising at least one impeller (18) surrounded by a ring sectorized (20) carried by a housing (16) and including a rim circumferential member (34) radially clamped on an annular rail (38) of the housing by resilient locks (140, 240) with a substantially C-shaped cross-section engaged axially on the crankcase rail and on the edge of the ring, characterized in that each ring sector is held on the rail of crank by at least one latch which is engaged only on a part circumferential end of the rim of the ring sector and on a corresponding part of the crankcase rail. 2. Floor according to claim 1, characterized in that the locks (140, 240) have a width (L ') or angular extent that is less than that (H) of a ring sector (22). 3. Floor according to claim 1, characterized in that each ring sector (22) is held on the casing rail (38) by a single latch (140), this latch being engaged on an end portion circumferential edge (34) of the ring sector and on a portion corresponding crankcase rail (38). 4. Floor according to claim 1, characterized in that each ring sector (22) is held on the casing rail (38) by two latches (240), these latches being engaged respectively on the parts circumferential end of the rim (34) of the ring sector and on corresponding parts of the crankcase rail (38). 5. Floor according to claim 1, characterized in that the locks (140, 240) are located at a distance from each other in the direction circumferentially, this distance being for example greater than or equal to width or the angular extent of a lock. 6. Floor according to claim 1, characterized in that each latch (140, 240) has an angular width or extent that is less than about half that of a ring sector (22). 7. Floor according to claim 1, characterized in that each latch (140, 240) has an angular width or extent that is less than about one third of that of a ring sector (22). 8. Floor according to claim 1, characterized in that each latch (140, 240) has an angular width or extent that is less than about a quarter of that of a ring sector (22). 9. Floor according to claim 1, characterized in that the locks (140, 240) are identical to each other. Turbomachine compressor or turbine, characterized in that he or she has at least one turbine or compressor stage according to claim 1. 11. Turbomachine, such as a turbojet engine or a turboprop engine of aircraft, characterized in that it comprises at least one turbine stage or compressor according to claim 1.